Apparatus and method for displaying images unto LED panels

ABSTRACT

The present teaching relates to method, system, medium, and implementations for LED display. A first signal is received that signals a timing for a next data transfer. In response to the first signal, a bit-based image block stored in a memory is transferred, via a bus connected thereto, to one of a pair of alternate buffers pointed to by a write buffer pointer, which is subsequently toggled to point to another of the pair of alternate buffers. A second signal is received that signals a timing for refreshing the LED display. In response to the second signal, the bit-based image block is retrieved from the one of the pair of alternate buffers pointed to by a read buffer pointer, which is then toggled to point to the other of the pair of alternate buffers. The lights of the LED display are then refreshed in accordance with control signals generated based on the bit-based image block.

CROSS REFERENCE TO RELATED APPLICATIONS

The present application is a continuation of U.S. patent applicationSer. No. 16/945,011, filed Jul. 31, 2020, which is related to U.S.patent application Ser. No. 16/945,093, filed Jul. 31, 2020, and U.S.patent application Ser. No. 16/945,130, filed Jul. 31, 2020, thecontents of which are hereby incorporated by reference in theirentireties.

BACKGROUND 1. Technical Field

The present teaching generally relates to LED display. Morespecifically, the present teaching relates to display information on LEDpanels.

2. Technical Background

In a society with ubiquitous electronics, display panels are almostpresent for every piece of electronic device. Light-Emitting-Diodes(LED) display panels are one of the most popular and are generally flatdisplay panels formed using modules or matrices of light emittingdiodes. LED display panels are bright, large, and long lasting and arewidely deployed at various public places such as airports, banks,stadiums, and hotels. They are also often used for displayingadvertisements as billboards. This industry has enjoyed rapid growth inthe last 10 years and still growing. y

A LED display panel includes a display panel (with LED light bulbs andpanel boards), controller(s), and LED drivers. In operation, LED driverssupply current to enable the LED light bulbs to emit lights, while thecontroller controls activities related to reading image data fromstorage and coordinating the operations of displaying the images ontothe LED panels. The controller does so by sending control signals to theLED drivers at specific timings to turn on and off the LED lights atdesired time instances in order to appropriately form images on thedisplay. A controller plays a critical role in the performance anddisplay effects of LED panels.

There are different types of LED panels. Some may be single-color, i.e.,each pixel on the panel has one light which is either on or off(binary). Some may be dual color, i.e., each pixel on the panel has 2lights, e.g., red and green, resulting in 4 different combinations: (1)red (red light on, green light off), (2) green (red light off, greenlight on), dark (both red and green lights off), and yellow (both redand green lights on). Some LED display panels are full-colored panels,with each pixel on the panel having three lights, corresponding to red,green, and blue. The number of intensity levels associated with eachlight determines the color resolution of the panel. The number ofintensity levels is controlled by the duration the light is turn on. Forexample, a light of a particular color may have 256 levels in itsintensity when lit and it is achieved by controlling the length of timethe light is kept on.

In many applications, a large sized LED display panel is needed. Forexample, a LED billboard deployed at a stadium, at an airport, or at astock exchange needs to be quite large to ensure visibility from adistance. Therefore, it is common to use many individual LED panels toform a larger LED display panel of a desired size. One example is shownin FIG. 1A, where a matrix of K rows and M columns of unit LED panels(smaller) forms a much larger LED display panel. When using multipleunit panels to form a larger one, the unit panels may be electricallyconnected in different ways. One exemplary way to connect 4×8 unitpanels is shown in FIG. 1B, where LED unit panels in each row are drivenelectrically by a controller from one end to the other. FIG. 1C shows adifferent panel connection. The controller controls the current to allrows presented in this example. From circuit connection point of view,it is also shown in FIG. 1D where the electronic connections are alongthe row direction from one unit panel to the next in the same row.

Each unit panel is a matrix of pixels. A picture of an exemplary unitpanel 110 with 16×32 pixels is provided in FIG. 1E. As discussed herein,each of the pixels has one or more lights. Each of the lights associatedwith each pixel in a unit panel may be controlled individually to be onor off with a certain time duration according to the image content at acorresponding location. FIG. 1F illustrates an example 8×8 full colorimage block 120, where each of the pixel has three color components,corresponding to red (R), green (G), and blue (B). Thus, as seen in FIG.1F, the color block 120 has in effect three 8×8 matrices, one being Rmatrix, one being G matrix, and one being B matrix. For example, pixel00 is composed of three values, R(00), G(00), and B(00), correspondingto its red component value, green component value, and blue componentvalue, respectively. Each of the color components (R, G, B) may berepresented by a number of bits, encoding the intensity level of thecorresponding color component. For instance, if each color component has3 bit, it yields 8 intensity levels; if each color component has 8 bits,it yields 256 intensity levels, etc. Such coded intensity levels willthen be used to control the timing and duration of LED lights whendisplay the image content on to the LED display panel.

An LED light associated with a pixel location of an LED panel is turnedon when both a row signal controlled by a row driver and a column signalcontroller by a column driver provide a current from both directions.One example is shown in FIG. 1G, where each row driver is configured todrive multiple rows of pixels and a column driver is configured to driveall columns as shown. If a particular LED light located at a certain rowand a certain column is to be turned on, the row signal passing throughthe certain row and the column signal passing through the certain columnare controlled to supply a current to that location. Column drivers areserially connected, both internally in a unit panel and across differentunit panels. Such connections may be determined based on how unit panelsare connected.

As illustrated in FIGS. 1B and 1C, unit panels forming a larger LEDdisplay panel may be connected in different ways. The column drivers oneach unit panel may also be connected in different ways. FIG. 1H showsan exemplary column connection scheme linking different column driverson each unit panel. In FIG. 1H, starting from the top column driver[1,1] in the left column, signals travel from column driver [1,1] tocolumn driver [K,1] in the bottom row and then back to the top rowcolumn driver [1,2] of the next column and then follow the same patternuntil reaching the last column driver [K,M]. As inside of each unitpanel is a matrix of pixels and a column signal may travel within eachunit panel.

There are synchronous and asynchronous operational modes in LED paneldisplay. In the synchronous mode, the images are supplied on-the-fly(e.g., streaming) so that the LED display has to be synchronous. In theasynchronous mode, images are stored first and at the time of displayingon an LED display panel, images are retrieved from storage and then aredisplayed accordingly. There are different traditional approaches toachieve asynchronous operation. One approach is to use a MicrocontrollerUnit (MCU) and the other is to use an MCU together with aField-Programmable Gate Array (FPGA). FIG. 2A illustrates a construct ofa traditional controller implementation using an MCU. As shown, there isan image storage 205, which stores images to be displayed on to an LEDdisplay panel, and an MCU 210. To display an image on to an LED displaypanel, the MCU 210 reads the image from the storage 205, process theimage data, transform the processed data in a suitable form screenrefreshing for the display, and generate and transmit appropriatecontrol signals (such as row/column signals, as clock signal CLK) to thedisplay panel controller. FIG. 2B provides an exemplary construct of theMCU 210. Typically, the MCU 210 comprises a flash read module 220 and aCentral Processing Unit (CPU) 230. The flash read module 220 is providedfor reading relevant information from the storage 205, which may includethe image data to be displayed and other peripheral information, e.g.,some operational parameters such as a front library 207. The image data,once read, is stored in a buffer 215 so that it can be accessed by theCPU 230 for processing. CPU 230 processes the image data, either from215 or directly from the flash read module 220. This may include anyspecial effect processing and transformation. The processed images mayalso be used by the CPU 230 to transform the image data to theinformation that can be used to refresh the LED. Such transformedrefreshing information may be stored in a SRAM storage 225 within theMCU and subsequently transmitted, via a GPIO interface, to the LEDdisplay panel. In this implementation, all operations on graphicalcomputation, data transformation, and screen refreshing are performed bythe software in MCU 210 running on the CPU 230. It is known that theprocessing speed using software is slower. Given the nature of LEDdisplay, such a slow speed using a solution as shown in FIG. 2B makes anMCU based solution typically only suitable for small LED displayscreens.

Another traditional solution that addresses the speed issue isillustrated in FIG. 2C with a solution for asynchronous LED displayusing a combination of an MCU 240 and a field programmable gate arrays(FPGA) 250. In this implementation, the MCU 240 is typically used forreading data and performing graphical computations. Data prepared by theMCU 240 is then transmitted to the FPGA 250, which is responsible fordata transformation and screen refreshing. As shown, each of the MCU 240and the FPGA 250 has its own SDRAM 245 and 255, respectively, forstoring image data. LCD interfaces or other interfaces with GPIOs areused between the MCU 240 and the FPGA 250 to transfer data.

Although the solution with MCU in combination of FPGA may alleviate thespeed issue associated with MCU only solution, there are otherdeficiencies associated with these traditional solutions to LED display.First, both approaches require significant memory resources. The MCUs inboth approaches need to read one or more entire images and store them inthe SRAM. This calls for significant SRAM resources for most MCUs.Accordingly, the size or number of LED lights of an application LEDscreen needs to be limited by the SRAM capacity of the MCU. For largescreens with a large number of pixels or full color LED screen, thesolution with MCU in combination with FPGA may be used for an enhancedspeed by having the FPGA to perform data transformation and screenrefreshing. However, additional drawbacks still exist. A typical concernis the cost associated with FPGA. To implement the same logic functions,the cost associated with FPGA is much higher than other solutions.

Thus, there is a need for methods and systems that address theshortcomings associated with the traditional solutions for LED display.

SUMMARY

The teachings disclosed herein relate to methods, systems, andprogramming for advertising. More particularly, the present teachingrelates to methods, systems, and programming related to exploringsources of advertisement and utilization thereof.

In one example, a method, implemented on a machine having at least oneprocessor, storage, and a communication platform capable of connectingto a network for LED display. A first signal is received that signals atiming for a next data transfer. In response to the first signal, abit-based image block stored in a memory is transferred, via a busconnected thereto, to one of a pair of alternate buffers pointed to by awrite buffer pointer, which is subsequently toggled to point to anotherof the pair of alternate buffers. A second signal is received thatsignals a timing for refreshing the LED display. In response to thesecond signal, the bit-based image block is retrieved from the one ofthe pair of alternate buffers pointed to by a read buffer pointer, whichis then toggled to point to the other of the pair of alternate buffers.The lights of the LED display are then refreshed in accordance withcontrol signals generated based on the bit-based image block.

In a different example, a system for LED display comprises a pair ofalternate buffers, a data transfer unit, and a refresh processor. Thepair of alternate buffers are for alternately storing bit-based imageblocks. The data transfer unit is configured for transferring, inresponse to a first signal signaling a timing for a next data transfer,a bit-based image block stored in a memory, via a bus connected thereto,to one of the pair of the alternate buffers pointed to by a write bufferpointer and then toggling the write buffer pointer to point to anotherof the pair of alternate buffers. The refresh process is configured forretrieving, in response to a second signal received, signaling a timingfor refreshing the LED display, the bit-based image block from the oneof the pair of alternate buffers pointed to by a read buffer pointer andtoggling the read buffer pointer to point to the other of the pair ofthe alternate buffers. Lights of the LED display are then refreshed inaccordance with control signals generated based on the bit-based imageblock.

Other concepts relate to software for implementing the present teaching.A software product, in accord with this concept, includes at least onemachine-readable non-transitory medium and information carried by themedium. The information carried by the medium may be executable programcode data, parameters in association with the executable program code,and/or information related to a user, a request, content, or otheradditional information.

In one example, a machine-readable, non-transitory and tangible mediumhaving data recorded thereon for LED display. A first signal is receivedthat signals a timing for a next data transfer. In response to the firstsignal, a bit-based image block stored in a memory is transferred, via abus connected thereto, to one of a pair of alternate buffers pointed toby a write buffer pointer, which is subsequently toggled to point toanother of the pair of alternate buffers. A second signal is receivedthat signals a timing for refreshing the LED display. In response to thesecond signal, the bit-based image block is retrieved from the one ofthe pair of alternate buffers pointed to by a read buffer pointer, whichis then toggled to point to the other of the pair of alternate buffers.The lights of the LED display are then refreshed in accordance withcontrol signals generated based on the bit-based image block.

Additional advantages and novel features will be set forth in part inthe description which follows, and in part will become apparent to thoseskilled in the art upon examination of the following and theaccompanying drawings or may be learned by production or operation ofthe examples. The advantages of the present teachings may be realizedand attained by practice or use of various aspects of the methodologies,instrumentalities and combinations set forth in the detailed examplesdiscussed below.

BRIEF DESCRIPTION OF THE DRAWINGS

This patent or application file contains at least one drawing executedin color. Copies of this patent or patent application publication withcolor drawing(s) will be provided by the Office upon request and paymentof the necessary fee.

The methods, systems and/or programming described herein are furtherdescribed in terms of exemplary embodiments. These exemplary embodimentsare described in detail with reference to the drawings. Theseembodiments are non-limiting exemplary embodiments, in which likereference numerals represent similar structures throughout the severalviews of the drawings, and wherein:

FIGS. 1A-1B (PRIOR ART) show exemplary arrays of LED unit panels forminga larger LED display panel via different panel connections;

FIG. 1C (PRIOR ART) shows an exemplary way to connect LED unit panels;

FIG. 1D (PRIOR ART) illustrates row connections of LED unit panels;

FIG. 1E (PRIOR ART) shows an exemplary LED unit panel with pixels;

FIG. 1F (PRIOR ART) illustrates an exemplary representation of an 8×8LED unit panel with full colors;

FIG. 1G (PRIOR ART) shows an exemplary way to drive pixels in an LEDpanel;

FIG. 1H (PRIOR ART) illustrates an exemplary way to connect LED unitpanels;

FIG. 2A (PRIOR ART) shows a traditional MCU based implementation of acontroller card;

FIG. 2B illustrates an exemplary construct of an MCU as a controllercard for LED display;

FIG. 2C (PRIOR ART) shows a traditional implementation of a controllercard with MCU and FPGA;

FIG. 3A depicts an exemplary high level system diagram of a controllerfor LED display with handshake, in accordance with an embodiment of thepresent teaching;

FIG. 3B is a flowchart of an exemplary process for a controller for LEDdisplay with handshake, in accordance with an embodiment of the presentteaching;

FIG. 3C depicts an exemplary high level system diagram of a controllerfor LED display with a shared clock, in accordance with an embodiment ofthe present teaching;

FIG. 3D is a flowchart of an exemplary process for a controller for LEDdisplay with a shared clock, in accordance with an embodiment of thepresent teaching;

FIG. 4A shows an exemplary representation of color image data tofacilitate LED display, in accordance with an embodiment of the presentteaching;

FIG. 4B shows an exemplary scheme of encoding a 1×3 image data blocks,in accordance with an embodiment of the present teaching;

FIG. 4C shows an exemplary compressed representation of an image data,in accordance with an embodiment of the present teaching;

FIG. 5 depicts an exemplary high level system diagram of a data transferunit, in accordance with an embodiment of the present teaching;

FIG. 6 is a flowchart of an exemplary process of a data transfer unit,in accordance with an embodiment of the present teaching;

FIG. 7 depicts an exemplary high level system diagram of a refreshprocessor, in accordance with an embodiment of the present teaching;

FIG. 8A shows different rows of pixels on an LED panel in a single colorbeing driven individually by different column signals, in accordancewith an embodiment of the present teaching;

FIG. 8B shows a representation of different rows of pixels on an LEDpanel in a single color being driven individually by different columndrivers, in accordance with an embodiment of the present teaching;

FIG. 9A shows a column signal driving different rows of pixels with asingle color via a snake type I connection, in accordance with anembodiment of the present teaching;

FIG. 9B shows a representation of a column driver in a snake type Iwiring for driving different rows of pixels, in accordance with anembodiment of the present teaching;

FIG. 9C shows content in registers when they are loaded with image datain a single color, in accordance with an embodiment of the presentteaching;

FIG. 9D shows the result of sequencing the bits in a register loadedwith image data in a single color to facilitate snake type I connection,in accordance with an embodiment of the present teaching;

FIG. 10A shows a column signal driving different rows of pixels in asingle color via a snake type II connection, in accordance with anembodiment of the present teaching;

FIG. 10B shows a representation of a column driver for driving differentrows of pixels in a single color via a snake type II wiring, inaccordance with an embodiment of the present teaching;

FIG. 10C shows the result of sequencing the bits in registers loadedwith pixels of different rows in a single color to facilitate snake typeII connection, in accordance with an embodiment of the present teaching;

FIG. 11A shows a column signal driving different rows of pixels in asingle color via a snake type III connection, in accordance with anembodiment of the present teaching;

FIG. 11B shows a representation of a column driver for driving differentrows of pixels in a single color via a snake type III wiring, inaccordance with an embodiment of the present teaching;

FIG. 11C shows the result of sequencing the bits in registers loadedwith pixels of different rows in a single color to facilitate snake typeIII connection, in accordance with an embodiment of the presentteaching;

FIG. 12A shows a row of pixels in dual color where each color componentbeing individually driven by a separate column signal, in accordancewith an embodiment of the present teaching;

FIG. 12B shows that separate column drivers drive two respective colorcomponents of pixels in dual color, in accordance with an embodiment ofthe present teaching;

FIG. 13A shows a row of pixels in dual color having both colorcomponents driven by the same column signal via a snake type Iconnection, in accordance with an embodiment of the present teaching;

FIG. 13B shows a representation of a column driver driving both colorcomponents of a row of pixels in dual color via a snake type Iconnection, in accordance with an embodiment of the present teaching;

FIG. 13C shows content in registers loaded with pixels in dual color, inaccordance with an embodiment of the present teaching;

FIG. 13D shows the result of sequencing the bits in registers loadedwith pixels in dual color to facilitate snake type II connection, inaccordance with an embodiment of the present teaching;

FIG. 14A shows a row of pixels in full color having each of the threecolor components driven by a separate column signal, in accordance withan embodiment of the present teaching;

FIG. 14B is a representation of three column drivers each of whichdrives a corresponding color component of a row of pixels in full color,in accordance with an embodiment of the present teaching;

FIG. 14C shows content in registers loaded with pixels in full color, inaccordance with an embodiment of the present teaching;

FIG. 14D shows the result of sequencing the bits in registers loadedwith pixels in full color to facilitate driving each of the differentcolor components separately, in accordance with an embodiment of thepresent teaching;

FIG. 15A shows a representation of driving each color componentseparately in snake type I connection, in accordance with an embodimentof the present teaching;

FIG. 15B shows the result of sequencing the bits in registers loadedwith pixels in full color to facilitate snake type II connections, inaccordance with an embodiment of the present teaching;

FIG. 16 is a flowchart of an exemplary process of a refresh processor,in accordance with an embodiment of the present teaching; and

FIG. 17 is an illustrative diagram of an exemplary computing devicearchitecture that may be used to realize a specialized systemimplementing the present teaching in accordance with variousembodiments.

DETAILED DESCRIPTION

In the following detailed description, numerous specific details are setforth by way of examples in order to facilitate a thorough understandingof the relevant teachings. However, it should be apparent to thoseskilled in the art that the present teachings may be practiced withoutsuch details. In other instances, well known methods, procedures,components, and/or circuitry have been described at a relativelyhigh-level, without detail, in order to avoid unnecessarily obscuringaspects of the present teachings.

The present teaching aims to address the deficiencies of the traditionalapproaches to asynchronous LED display. As discussed herein, thetraditional systems either require significant memory resources ordemand costly solutions. The present teaching discloses a system andmethod for asynchronous LED display that requires insignificant memoryresources and is cost effective. In addition, the present teaching isdirected to a solution that can be flexibly used for LED screen with LEDunit panels connected in different ways. Furthermore, the disclosedsystem and method are fast so that they can be used for displaying onlarge LED panels.

Specifically, the present teaching discloses a controller system for LEDdisplay with a data transfer unit and a refresh processor, both clockedby the same clock signal, and a small data storage bridging the datatransfer unit and the refresh processor for buffering the image datafrom the data transfer unit which is needed by the refresh processor forthe near future.

FIG. 3A depicts an exemplary high level system diagram of an LED displaycontroller 300 with handshake, in accordance with an embodiment of thepresent teaching. As seen, the LED display controller 300 takes imagedata from a storage 310 and outputs a number of signals that are used tocontrol the display on an LED display panel. The storage 310 may be aflash memory or any other form of data storage that facilitates fastaccesses. The output signals from the controller 300 may includerow/column signals, clock signal, etc., where the row/column signals areused to drive rows and columns to control the states of the lights(one/off and/or duration of each state to achieve intensities determinedbased on the pixel content) associated with each of the pixels on theLED screen. Such control signals are generated appropriately inaccordance with the image content.

The LED display controller 300 comprises a data transfer unit 320, aSRAM storage 330, a refresh processor 340, and a handshake manager 307.In this illustrated embodiment, the operations of the data transfer unit320 and the refresh processor 340 are coordinated via somesynchronization signals such as a certain handshake protocol which is,e.g., managed by the handshake manager 307. Through such coordination,the data transfer unit 320 and the refresh processor 340 aresynchronized so that the data transfer unit 320 supplies image data to asmaller buffer 330 and the refresh processor 340 retrieves image datafrom the buffer on the-the-fly. On each supply of an image data block,it may be followed by a synchronized operation of the refresh processor340. Based on this operational mode, only a limited image data needs tobe stored in the SRAM, significantly reducing the requirement on thememory resource.

When synchronized via a handshake protocol, once the data transfer unit320 stores an image data block in first one of the alternate buffers, itmay send a handshake signal to the handshake manager 307 to indicatethat it completes data transfer to the first buffer and then proceeds totransfer a next image block into the alternate buffer. Once that isaccomplished, the data transfer unit 320 waits until receiving ahandshake signal from the refresh processor 340 indicating that theimage block in the first buffer has been retrieved so that the firstbuffer can now be used to load another image data block. For the refreshprocessor 340, upon receiving a handshake signal from the data transferunit 320 indicating that image data block is now available in a firstbuffer, the refresh processor 340 proceeds to retrieve the image datablock from the first buffer for its processing. Upon retrieving thefirst image block from the first buffer, the refresh processor 340 sendsits handshake signal to the data transfer unit 320 (e.g., via thehandshake manager 307) to inform the data transfer unit 320 that thefirst image block has been retrieved.

Although synchronized, the data transfer unit 320 and the refreshprocessor 340 are operate on different buffers at each specific timeinstance. However, so long as the processing speed of both can match,the size of the buffer 330 or SRAM storage 330 can be kept very small.In this illustrated embodiment, the SRAM storage includes two buffers330-1 and 330-2, both of which may be of the same size, e.g., determinedby the size of the image data block on each read. The choice of the sizeof the buffers may be determined based on different considerations. Forinstance, it may correspond to the width of an image, the height of theimage, or an amount of data that refresh processor 340 takes in onebatch for its processing. If it corresponds to the width of the image tobe displayed, it may facilitate the refresh processor 340 to process onerow of the image at a time. Similarly, a buffer size equal to the lengthof an image can facilitate the refresh processor 340 to process, witheach batch, an entire column of pixel data. The size of the buffer mayalso be of any size that an application demands. Due to the fact thateach buffer is of the size of each read, the amount of data to bebuffered in 330 is much smaller than an entire image.

As at each moment, the data transfer unit 320 and the refresh processor340 are operating on different buffers, another aspect ofsynchronization may be achieved via pointers. That is, a write pointerpointing to one of the two buffers for loading, by the data transferunit 320, an image block into that buffer and a read pointer pointing tothe other alternate buffer for reading, by the refresh processor 340, toread from the other alternate buffer for display related processing. Thedata transfer unit 320 toggles the write pointer after it loads am imageblock into one of the buffers and after it receives the next handshakesignal from the refresh processor 340 indicating the previous imageblock stored therein has been retrieved. Similarly, the refreshprocessor 340 toggles the read pointer after it reads an image blockfrom a buffer pointed to by the read pointer and receives a handshakesignal from the data transfer unit 320 indicating that new image datahas been loaded into the other alternate buffer.

FIG. 3B is a flowchart of an exemplary process for the LED displaycontroller 300 with handshake, in accordance with an embodiment of thepresent teaching. At 305, the data transfer unit 320 perform graphicalcomputation on image data stored in the image data storage 310. Suchgraphical computation may be optional and the processing may include,e.g., certain special effect treatment on the images. The preprocessingmay also include other types of data processing. For example, accordingto one aspect of the invention, the original image data may bere-organized. A color image is generally provided with multiple frames,each frame corresponding to one color component such as red, green, orblue. With this organization, data bits of different colors are storedin different frames. One possible processing is to reorganize the imagedata so that corresponding bit from each color component may be storedtogether. For example, if a full color image has an 8-bit colorrepresentation in each of the three color frames in red, green, andblue. After the re-organization, the converted image data has 8 frames,each pixel having three bits, each being a corresponding bit from arespective color component. Such preprocessed image data is then storedinternally in the data transfer unit 320.

In operation, the data transfer unit 320 may then initialize, at 315,buffer pointers pointing at alternate buffers. For example, theinitialization may set the write and read pointers to point at both oneof the alternate buffers, e.g., buffer 330-1. To start the data transferoperation, the data transfer unit 320 then obtains, at 325, the nextread instruction (details discussed below) for retrieving a block ofimage data from its internal storage. In some embodiments, the readinstruction includes a starting address of the image block to be readfrom the internal storage as well as a length of the image block.

To ensure high speed read, the data transfer unit 320 maps, at 335, theaddress of the image block directly on the bus connected with thestorage to facilitate reading the image block via hardware. It thentransfers, at 345, the read image block to the buffer that the writepointer is pointing at. Once completing the transfer of the first imageblock to the buffer 330, the data transfer unit 320 sends, at 347, ahandshake signal to the refresh processor 340 via the handshake manager307, which informs the refresh process 340 that the image data block isnow available in the buffer.

After sending out the handshake signal, the data transfer unit 320proceeds to write the next image data block into the alternate buffer.To do so, the data transfer unit 320 toggles, at 350, the write pointerto the alternate buffer and retrieves, at 355, the next read instructionfor reading the next image block and maps the address of the next imageblock on the bus to facilitate fast reading. The newly retrieved imageblock is then transferred, at 360, to the alternate buffer pointed to bythe write pointer. At this point, the data transfer unit 320 checks at365, whether a handshake signal is received from the refresh processor340. Such a handshake signal from the refresh processor 340 indicatesthat the image data stored in the first buffer has been retrieved sothat is can now be used to transfer a new image block. When thathappens, the data transfer unit 320 toggles, at 350, the write pointerto point at the first alternate buffer and load the next image block bycarrying out the steps 355 and 360. The process continues in such loopswith the coordination achieved via handshake signals and bufferpointers.

The refresh processor 340 also acts on handshake signals. With the readpointer initialized to point at the first of the two buffers, i.e.,330-1, the refresh processor 340 first checks, at 367, whether itreceives a handshake signal from the data transfer unit 320 indicatingthat image data has been transferred to buffer 330-1. When it receivesthe handshake signal, the refresh processor 340 accessed, at 370, thefirst image block stored in the first buffer 330-1 based on the readpointer (which points at buffer 330-1). Upon the first image blockretrieved from buffer 330-1, the refresh processor 340 toggles, at 375,the read pointer to point at buffer 330-2 and then sends, at 380, ahandshake signal to the data transfer unit 320 to indicate that theimage data buffered in 330-1 has been retrieved so that it can now beused to transfer new image data.

Then the refresh processor 340 proceeds to carry out the processing onthe retrieved image data, including sequencing, at 385, the bits in theretrieved image data according to the connection pattern of the LEDdisplay, generating, at 390, control signals based on the image content,and then refreshing, at 395, the LED screen using the control signals.According to the present teaching, too transform the accessed image datato control signals, the refresh processor 340 may re-sequence, ifneeded, the image data bits in the first image data block. The way imagebits are sequenced depends on the wire connection pattern. In somesituations, the sequencing may be executed using microcodes, which isprogrammed specifically with respect to the connection pattern of thedriving connections in the unit panels of the LED display panel. Basedon the sequenced image data, the refresh processor 340 then generatesvarious control signals that are used to realize the image content onthe LED display panel. After completing the processing of the retrievedimage data, the refresh processor 340 checks, at 367, to see if the datatransfer unit 320 sends a next handshaking signal to indicate that imagedata has been transferred into the other alternate buffer 330-2. If not,the refresh processor 340 waits until the new image data is madeavailable in the alternate buffer.

FIG. 3C depicts another exemplary high level system diagram of a LEDdisplay controller 301 with a shared clock, in accordance with anembodiment of the present teaching. As can be seen, the LED displaycontroller 301 herein is similarly constructed as that of 300 exceptthat the data transfer unit 320 and the refresh processor 340 are nowcoordinated via a common clock signal generated by a clock signalgenerator 309 (rather than via handshake managed by the handshakemanager 307 as shown in FIG. 3A). Similarly, the LED display controller300 comprises a data transfer unit 320, a SRAM storage 330, a refreshprocessor 340, and a clock signal generator 309. The clock signalgenerated by the clock signal generator 309 may be used by both the datatransfer unit 320 and the refresh processor 340 so that the datatransfer unit 320 and the refresh processor 340 are synchronized basedon the same clock. As discussed herein, the data transfer unit 320retrieves image data from the storage 310, processes the retrieved data,and place it on the SRAM storage 330. The refresh processor 340 accessesthe processed data from SRAM storage 330, transform the accessed imagecontent into control signals that can be used to display the imagecontent on the LED screen, and output such control signals to the LEDdisplay panel.

In this embodiment, as both the data transfer unit 320 and the refreshprocessor 340 are clocked on the same signal, the frequency by which therefresh processor needs new image data also governs the frequency bywhich the data transfer unit 320 places processed image data into theSRAM storage 330. Similarly, as the processing speed of the datatransfer unit 320 keeps up with that of the refresh processor, the sizeof the SRAM storage can be kept very small. To operate, on each clock,the data transfer unit 320 may retrieve, e.g., on the rising edge of thefirst clock signal, image data from the storage 310, process the imagedata, and save processed image data in the first buffer 330-1 on, e.g.,the falling edge of the first clock signal. Then, on the rising edge ofthe second clock, the data transfer unit 320 may retrieve the next batchof image data, process the image data, and save the processed image datain the second buffer 330-2 on, e.g., the falling edge of the secondclock. Acting on the same clock signals, the refresh processor 340 mayaccess the processed image data stored in the first buffer 330-1 on,e.g., the rising edge of the second clock, transform the processed imagedata into control signals, and output the transformed signals on, e.g.,the falling edge of the second clock. The refresh processor 340 may thenproceed to access, e.g., on the rising edge of the third clock signal,the processed image data from the second buffer 330-2, transform theaccessed image data into control signals, and output the controlsignals. While the refresh processor 340 is accessing the processedimage data buffered in the second buffer 330-2, the data transfer unit320 retrieves next batch of image data from storage 310, process it, andalternately save the processed image data back in buffer 330-1 again. Inthis manner, by ensuring that the data transfer unit 320 and the refreshprocessor 340 can act in concert and in sync, the SRAM storage 330 canbe kept small.

FIG. 3D is a flowchart of an exemplary process for the LED displaycontroller 301 with a shared clock, in accordance with an embodiment ofthe present teaching. At 302, the data transfer unit 320 performsgraphical computation or other type of image preprocessing on image datastored in the image data storage 310. As discussed herein, suchpreprocessed image data may be stored in a memory internally in the datatransfer unit 320. To facilitate alternately storing image data in thebuffer 330, the data transfer unit 320 may initialize, at 312, write andread buffer pointers to initially point at, e.g., buffer 330-1. In thisimplementation, to synchronize the operation, the data transfer unit 320and the refresh processor 340 operate based on the clock signalgenerated by the clock signal generator 309. First, the data transferunit 320 receives, at 322, the next clock signal and then act on theclock signal to retrieve, at 332, the next read instruction (detaileddiscussed below). As discussed herein, a read instruction mayincorporate both a starting address of the image block to be read aswell as a length of the image block.

To keep up with the speed of the refresh processor 340, the datatransfer unit 320 maps the address of the image block directly on a busthat connects to the internal memory and then transfers, at 342, theimage block to the buffer, e.g., 330-1, to which the write pointer ispointing. Once completing the transfer of the first image block to thebuffer 330, the data transfer unit 320 waits to receive, at 352, a nextclock signal. At the same time, this next clock signal is also receivedby the refresh processor 340 and can be relied on to start tosynchronize the operations of both from this point on. Acting on thenext clock signal, the data transfer unit 320 retrieves, at 354, thenext read instruction for reading the next image block from the internalmemory and maps the address of the next image block on the bus tofacilitate fast transfer. To prepare for the next buffering, the bufferpointer is toggled, at 362, to point to the alternate buffer, e.g.,330-2. After the write pointer is switched to point at buffer 330-2, thedata transfer unit 320 transfers, via hardware at 364, the next imageblock to buffer 330-2. Then the operation of the data transfer unit 320repeats the cycle by returning to step 352.

Also acting on the next clock signal, the refresh processor 340 takesactions by first accessing, at 372, the first image block stored inbuffer 330-1, pointed to by the current read pointer. Once the imagedata in buffer 330-1 is retrieved, the refresh processor 340 toggles, at374, the read pointer to point to the alternate buffer 330-2, indicatingthat the next buffer to read image data is from buffer 330-2. Totransform the accessed image data to control signals, the refreshprocessor 340 sequences, if needed at 382, the bits in the image datavia microcodes, which are programmed specifically with respect to theconnection pattern of the unit panels in the current LED display panelso that bits in the image data can be sequenced in a way suitable forthe current connection pattern. Based on the re-sequenced image data,the refresh processor 340 then generates, at 384, various controlsignals to be used for refreshing, at 392, lights for pixels of the LEDdisplay panel to render the image data on the LED display panel. Thenthe operation of the refresh processor 340 repeats by returning to step352.

Details related to how the present teaching operates are disclosedbelow. FIG. 4A shows an exemplary organization of image data in fullcolor arranged to facilitate LED display, in accordance with anembodiment of the present teaching. A conventional image corresponds toan array of pixels. When it is in full color, such as 120 in FIG. 1E,the image has three images frames, each of which corresponds to onecolor components R, G, and B. Depending on the resolution, each pixel ofeach of the color frame is coded by a number of bits, e.g., 8 bitsrepresenting 256 intensities in that color component space. Tofacilitate the present teaching, bits in an image information isorganized as illustrated in FIG. 4A. For each image in full color witheach color component having 8 bits, the image (410) is represented by 8frames (410-1, . . . , 410-8)), each of which represents one bit fromeach color frame. For example, in frame 1 410-1, the first pixel 00 isrepresented by three bits, one bit from each color frame on thecorresponding bit position. That is, R00⁰ is the lowest bit of the 8 bitrepresentation of the R component for pixel 00, G00⁰ is the lowest bitof the 8 bit representation of the G component for pixel 00, and B00⁰ isthe lowest bit of the 8 bit representation of the B component for pixel00. In addition, R00¹ is the second lowest bit of the 8 bitrepresentation of the R component for pixel 00, G00¹ is the secondlowest bit of the 8 bit representation of the G component for pixel 00,and B00¹ is the second lowest bit of the 8 bit representation of the Bcomponent for pixel 00 (not shown). All the way, R00⁷ is the highest bitof the 8 bit representation of the R component for pixel 00, G00⁷ is thehighest bit of the 8 bit representation of the R component for pixel 00,and B00⁷ is the highest bit of the 8 bit representation of the Bcomponent for pixel 00. Similarly, for other pixels of a full colorimage, image information may be organized in the same way. For example,FIG. 4A shows that how color information for pixels 01 and 02 isorganized.

With this organization, color information of the same bit for each pixelis now stored together so that it is possible to read such informationwithout going across different color frames. It is significant becauseit enable a way to compress the image data and at the same timefacilitate a more effective information transformation for refreshingthe LED display as described below. FIG. 4B shows an exemplary scheme ofencoding a 1×3 image data block 430, in accordance with an embodiment ofthe present teaching. As shown, the 1×3 image data block includingpixels 00, 01, and 02 which is represented by the bit block 420 with 8rows of bits representing the full color of the 3 pixels. 420 has 8blocks of bits, corresponding to block 0 BLK0 with a read startingaddress 0 (relatively) and length (or number of bits) 9, . . . , block 7BLK7 with a starting address of 7×L and length 9, where L is the lengthof each frame (see FIG. 4A).

In asynchronous LED display, an original image data may first bepreprocessed and the processed image data may then be stored before thedisplay. In some embodiments, the preprocessing may be done offline. Forexample, the data transfer unit 320 may read the original image datafrom storage 310, preprocess the image data by performing the bit basedre-organization as described in FIGS. 4A-4B, and such re-organized imagedata (bit based) may then be stored internally to the data transfer unit320 to allow subsequent data access in high speed. To facilitatetransferring bit based image data or an operation called bitCopy, thepresent teaching discloses an image compression scheme in the form ofbitCopy instructions. Such bitCopy instructions control the datatransfer unit 320 in data transfer operation and each of theinstructions is encoded with a starting address and a length of eachimage block to be transferred. For example, BLKi[SAi, Li] corresponds toa generic bitCopy instruction with SAi representing the starting addressand Li representing the number of bit to read. Given that, bitCopyinstruction BLK2[SA2, L2] is an instruction to instruct the datatransfer unit 320 to read bits starting at address SA2 for L2 number ofbits. Based on this representation, to traverse the entire image inreading, it can be encoded in a much compressed form with a series ofbitCopy instructions which, when executed by the data transfer unit 320,will traverse the entire bit based image data.

FIG. 4C shows the transformation from the original image data tocompressed bitCopy instructions to traverse the image, in accordancewith an embodiment of the present teaching. As seen, starting with animage with color frames 120, the bits in the image data are re-organizedto a form bit based image data 410, which is then further converted intoa series of bitCopy instructions 440 to be used to traverse the entireimage in the bit based data space. As seen, while the original image isorganized in the conventional way to include 3 color frames, the bitbased image as depicted in FIG. 4A stores corresponding color bits fromdifferent color frames together in the same reorganized frame. ThebitCopy instructions is much compressed as compared with the originalimage data. As such, reading them by the data transfer unit 320 is fast.In combination with the design to map the address of bit reading on thebus, it makes the data transfer unit 320 read fast keeping up with theclock cycles of the refresh processor 340.

FIG. 5 depicts an exemplary high level internal system diagram of thedata transfer unit 320, in accordance with an embodiment of the presentteaching. In this illustrated embodiment, the data transfer unit 320comprises an image data partition unit 510, an image data preprocessingunit 520, a partition index generator 550, a bitCopy instructiongenerator 560, and a bitCopy Unit 580. FIG. 6 is a flowchart of anexemplary process of the data transfer unit 320, in accordance with anembodiment of the present teaching. In some embodiments, there may be aportion of the operation for preprocessing operation and an onlineportion of the operation in which the data transfer unit 320 coordinateswith the refresh processor 340 to deliver on-the-fly LED display. Duringthe preprocessing process, an original image data may be preprocessedfor, e.g., special effect, conversion to bit based image data, andgeneration of bitCopy instructions. Such preprocessed image datafacilitates the online processing. The online portion of the operationis an on-the-fly process in which the data transfer unit 320 works inconcert with the refresh processor 340 to read the entire image bycontinuously accessing the next bitCopy instruction, reading the nextpreprocessed bit based image block according to the bitCopy instruction,and then placing alternately the read image block into one of thebuffers.

In FIG. 6 , steps in the left column (steps 600-640) correspond to thepreprocessing process and steps in the loop on the right column (steps650-690) correspond to the online process. During the preprocessingphase, the image data partition unit 510 first reads and preprocesses,at 600, the original image data from the storage 310. In someembodiments, the original image may be partitioned, at 610, intodifferent original image blocks for, e.g., facilitating repeated partialreading of image data during the online process. The partitioned imagedata is then processed, at 620, by the image data preprocessing unit 520to generate the bit based image blocks (according to what is describedin FIGS. 4A-4B). Such preprocessed bit based image blocks are stored inan internal SRAM storage 530. Each bit based image block stored in theinternal SRAM, there is a corresponding starting address to locate theblock and a length associated with the bit based image block. Suchinformation associated with each block may be transmitted to thepartition index generator 550 to facilitate the generation of bitCopyinstructions.

Based on the image data partition information and the starting addressand length information associated with each bit based image block, thepartition index generator 550 creates, at 630, an index for each of thebit based image blocks. Each index for a corresponding bit based imageblock may include an ID for the block, a starting address in the storage530 where the block starts, and a length or a number of bits occupied inthe storage 530. Based on such indices, the bitCopy instructiongenerator 560 generates, at 640, bitCopy instructions that can be usedduring the online process to read the bit based image blocks. In someembodiments, each bitCopy instruction may be directed to one bit basedimage block and when it is executed, it enables the bit based imageblock to be read out from the storage 530. In some embodiments, it isalso possible to have each bitCopy instruction to read more than one bitbased image blocks. The size of the buffer may be adjusted toaccommodate multiple bit based image blocks. The specific way to encodethe image data via bitCopy instructions may be application dependent. Inthe disclosure below, it is assumed that each bitCopy instruction is forreading one bit based image block. However, such an assumption is merelyfor illustration, rather than limitation, and does not limit the scopeof the present teaching.

Although the preprocessing operation is discussed to correspond to anoffline process, i.e., it is completed prior to the online processingstarts, it may also be possible that the preprocessing is carried outalso as a part of an online operation, i.e., it is performed on-the-fly.That is, the image preprocessing as described herein (reorganizing thebits in the original image data in accordance what is disclosed in FIGS.4A-4B) and the generation of bitCopy instructions may also be carriedout on-the-fly. Such a working mode is also a part of the presentteaching even though it may require additional coordination and/orclock/handshake management to ensure that the preprocessing and bitCopyinstruction generation may keep up with the speed of refreshing anddisplay speed of the LED screen. The discussion below focuses the onlineprocess involving bitCopy operation, refreshing, and displaying. It ismerely for illustration rather than limitation and should not beconstrued to limit the scope of the present teaching.

As discussed herein, the on-the-fly process requires synchronizationbetween the data transfer unit 320 and the refresh processor 340 basedon either a handshake protocol or a commonly shared clock. The onlineprocess is an iterative process. From the perspective of the datatransfer unit 320, in each cycle, the bitCopy unit 580 acts on each ofthe generated bitCopy instructions, maps the starting address indicatedin each of the bitCopy instructions on the bus 540, and retrieves (fromthe internal SRAM 530) a bit based image block via hardware operation,and places the retrieved bit based image block in one of the alternatebuffers. As shown in FIG. 6 , the bitCopy unit 580 first receives, at650, a next synchronization signal (handshake signal or a clock signalCLK). Acting on the synchronization signal, the bitCopy unit 580retrieves, at 660, the next bitCopy instruction and maps the startingaddress and length (from the bitCopy instruction) on the bus 540. Thisenables the bitCopy unit 580 to read, at 670, the bit based image blockfrom SRAM 530 via hardware and then store, at 680, the read bit basedimage block in one of the two buffers 330 based on the current bufferpointer 570. Once the bit based image block is saved in the buffer, thebitCopy unit 580 toggles, at 690, the buffer pointer 570 so that it nowpoints at the alternate buffer. Once that is done, the online processproceeds to step 650 to start the next cycle. The process continuesuntil the entire image is retrieved.

As discussed herein, during the online process, the refresh processor340 works with the data transfer unit 320 in concert by retrieving thebit based image blocks stored in the alternate buffers 330-1 and 330-2(see FIG. 3 ), transform the data in each bit based image block intosignals that may be used to refresh the lights associated with pixels onthe LED screen to achieve the display effect dictated by the imagecontent. FIG. 7 depicts an exemplary high level system diagram of therefresh processor 340, in accordance with an embodiment of the presentteaching. In this illustrated exemplary embodiment, the refreshprocessor 340 interfaces with the buffers 330 via the bus 540 and theLED display panels 770. Internally, the refresh processor 340 comprisesa connection-based sequencer 700, a special buffer 750, and an LEDrefresh unit 760. The connection-based sequencer 700 is provided tore-arrange the bits in a bit based image block based on how the unitpanels are connected so that the lights associated with the pixels onthe LED screen may be appropriately refreshed in a consistent manner.The special buffer 750 is a list storing result from theconnection-based sequencer. The input to 750 is provided according tothe sequence of column signals. The output is arranged in a manner thatall columns need to output 1-bit at each clock cycle. For example, theorder of bits from 700 to be input to 750 is: 32-bits of column 0,32-bits of column 1, 32-bits of column 2, . . . , 32-bits of column N.The output of 750 is in the order of: bit31 of all columns, bit 30 ofall columns, bit 29 of all columns, . . . , bit0 of all columns. Thestored image information may then be used by the LED refreshing unit 760to transform into control signals based on the image content, i.e., thecolor representation of the pixels in the image.

The connection-based sequencer 700 comprises an image bits sequencer720, which takes bits in a bit based image block from an alternatebuffer (based on the buffer pointer) as input and produces a series ofbits arranged appropriately with respect to the connection pattern. Tore-arrange the bits, the image bits sequencer 720 may sequence the bitsor microcodes retrieved from storage 730 may be execute for thatpurpose. The microcodes used for sequencing the bits may be determinedbased on information stored in 740 that signifies a specific connectionpattern of the current LED display screen. Such information is used toselect the microcodes to be used to sequence the image bits. In someembodiments, storage 740 may store different connection profiles.Storage 730 may store different corresponding microcodes, each of whichmay be provided to support some connection profiles. In operation,information may be set in storage 740 to indicate the current connectionpattern and such information may be used to activate a corresponding setof microcodes for appropriately processing the image bits from a bufferin a manner consistent with the connection pattern. FIGS. 8A-15B showvarious exemplary ways to re-sequence bits in different circumstances.

FIG. 8A shows two different rows of single color pixels on an LED panelbeing driven individually by different column signals, in accordancewith an embodiment of the present teaching. There are two rows of 8pixels, row 810 with pixels 00-07 and row 820 with pixels 10-17. In thisconfiguration, each of the rows is driven by a separate column signal,respectively. That is, column signal 0 830 drives the pixels 00-07 inthe first row 810 on an LED screen and column signal 1 840 drives pixels10-17 in the second row 820 on the same display screen. FIG. 8B shows adifferent representation of the same where each column signal is driventhrough each row by a separate column driver, in accordance with anembodiment of the present teaching. In this representation, although thecolumn driver 850 that sends column signal 0 830 to pixels 00-07 viaseparate lines, such lines may represent the pins of a chip and they maybe connected internally in the driver so that the effect is the same aswhat is presented in FIG. 8A, i.e., the column signal 0 830 flows frompixel 00 to 01 to 02, . . . , to 07 in a serial manner. The similar canbe said about how the column driver 860 delivers column signal 1 840 toeach of the pixels 10, 11, 12, . . . , 17. When each row is driven by aseparate column signal, as shown in FIGS. 8A and 8B, bits read fromalternate buffers do not need to be re-sequenced.

In most LED display operations, a column signal drives through pixelsacross multiple rows. To deliver a column signal to pixels acrossdifferent rows, the column signal needs to traverse pixels in an LEDdisplay screen formed by multiple LED unit panels in a manner consistentwith both how pixels inside each unit panel are linked and how LED unitpanels are connected to form a larger LED display screen. Depending onthe connection pattern, a column signal will traverse pixelsdifferently. Because of that, the bits of the image data need to besequenced accordingly to accommodate the connection pattern.

FIG. 9A shows a column signal driving two rows of pixels in a singlecolor via a snake type I connection, in accordance with an embodiment ofthe present teaching. As seen, there are two exemplary rows of pixels910 (with pixels 00-03) and 920 (with pixels 10-13) and all pixels aresingle colored. A column signal 930 is used to drive pixels in both rowsin a connection pattern called snake type I, by which the column signal930 starts from the top row and flows from first pixel 00 in the firstrow 910 to first pixel 10 in the second row 920, and back to first rowto flow to second pixel 01, and to the second pixel 11 in the second row11, back to the first row again to drive the third pixel 02, back downto the third pixel 12 of second row 920, . . . , etc. FIG. 9B shows adifferent representation of snake type I connection in driving a columnsignal to traverse two rows of pixels of a single color, in accordancewith an embodiment of the present teaching. The column signal 930 isdriven by a column driver 940 to the pixels. As seen, there aredifferent links from the column driver 940 to different pixels. Form theleft most link to the right most link from the column driver, the orderof traversing the pixels are 00, 10, 01, 11, 02, 12, . . . , and 13,identical to what is presented in FIG. 9A.

To facilitate such a traversing order, the bits in the bit based imageblock read from the alternate buffers 330 may need to be re-sequenced.This is illustrated in FIGS. 9C and 9D. FIG. 9C shows content inregisters when two rows of bit based image data in a single color isloaded, in accordance with an embodiment of the present teaching. Asillustrated, the first row is P0 950 and the second row is P1 960. Inthis example, the first row has 32 bits starting from A31 as, e.g., themost significant bit, to A0 as, the least significant bit. The secondrow also has 32 bits starting from B31 as, the most significant bit, toB0 as, the least significant bit. If the connection pattern is snaketype I, then along the traverse path, the sequence of bits will be A31,B31, A30, B30, A29, B29, . . . , A1, B1, A0, and B0. This is derived bytraveling starting from the first bit in the first row, down to thefirst bit in the second row, back to the second bit in the first row, tothe second bit in the second row, . . . . Thus, to satisfy this traversepath due to snake type I connection pattern, the bits in 950 and 960need to be re-sequenced to generate re-sequenced bit stream as shown inFIG. 9D, which shows the result of sequencing the bits in 950 and 960 tofacilitate snake type I connection, in accordance with an embodiment ofthe present teaching.

As can be seen below, when the connection pattern changes, the bits inthe same registers 950 and 960 need to be sequenced differently in orderto accommodate the connection pattern. FIG. 10A shows a connectionpattern called snake type II, in accordance with an embodiment of thepresent teaching. With this connection pattern, the column signal 1030traverses pixels starting from the first pixel 10 in the second row 1020to the first pixel 00 of the first row 1010, back to the second pixel 11in the second row 1020 and to the second pixel 01 in the first row 1010,then back again to the second row 1020 to the third pixel 12, and returnto the third pixel 02 of the first row 1010, . . . . FIG. 10B shows adifferent representation with a column driver 1040 for driving thecolumn signal 1030 via a snake type II connection, in accordance with anembodiment of the present teaching. As shown, for two rows 1010 and1020, the column driver 1040 as links to different pixels in differentrows. Starting from the left most link from the column driver 1040, itdelivers the column signal 1030 to pixel 10 in the second row 1020, topixel 00 in the first row 1010, to the second pixel 11 in the second row1020, to the second pixel 01 of the first row 1010, etc. with the sametraverse order as what is shown in FIG. 10A. When the connection patternchanges, bits are traversed in a different order. To accommodate that,image bits from a bit based image block also need to be sequenceddifferently.

FIG. 10C shows image bits re-arranged based on the image content shownin FIG. 9C when the wiring connection pattern is snake type II, inaccordance with an embodiment of the present teaching. Consistent withthe traversal order according to snake type II connection, the bits asshown in FIG. 10C are now in an order of B31, A31, B30, A30, B29, A29, .. . , B1, A1, B0, and A0. This result may be obtained via different waysto re-arrange the bits loaded from the SRAM 330. One is via sequencingperformed by the image bits sequencer 720. That is, for each connectiontype, there is a different sequencing operation to re-arrange the bitsin a way that is appropriate for the connection type. Another way is toexecute a suitable set of microcodes corresponding to the connectiontype. Yet another different way is to combine the sequencing andmicrocodes. For example, the image bits sequencer 720 may be provided tosequence the image bits according to snake type I connection. If theactual connection type is snake type II, microcodes may be executedbased on the sequenced result in snake type I connection to rearrangethe bits in snake type I arrangement to achieve other connection types.As seen, to convert from snake type I bit arrangement to snake type IIarrangement, a simple operation of flipping the order of each pair ofbits will achieve the conversion.

FIG. 11A shows a connection pattern called snake type III, in accordancewith an embodiment of the present teaching. As shown therein, there aretwo rows of pixels 1110, and 1120, both driven by the same column signal1130 with a traverse path going through pixels in the order of firstpixel 00 of the first row 1110, to the first pixel in the second row1120, to the second pixel 11 in the same second row 1120, back to thesecond pixel 01 of the first row 1110, to the third pixel 02 of the samefirst row 1110, to the third pixel 12 of the second row 1120, and againthe fourth pixel 13 of the same second row 1120, . . . , until allpixels of both rows traversed in this connection pattern. FIG. 11B showsa different representation of the snake type III connection with acolumn driver driving through pixels in different rows with thisconnection pattern, in accordance with an embodiment of the presentteaching. The links from the column driver starting from the left mostlink sends the column signal 1130 to pixel 00 in the first row 1110, topixel 10 of the second row 1120, to pixel 11 of the same second row1120, and then to the second pixel 01 of the first row 1110, and to thethird pixel 02 of the same first row 1110, . . . , in the same manner aswhat is shown in FIG. 11A.

Similarly, with snake type III connection pattern, bits in a bit basedimage block from an alternate buffer need to be sequenced as discussedherein according to this connection pattern. FIG. 11C shows the resultof sequencing the bits in registers 950 and 960 to facilitate snake typeIII connection, in accordance with an embodiment of the presentteaching. As seen, the original sequence of the bits in registers 950and 960 as shown in FIG. 9C are now re-sequenced to have the order ofA31, B31, B30, A30, A29, B29, B28, A28, A27, . . . , A3, B3, B2, A2, A1,B1, B0, A0. As discussed herein, instead of using the image bitssequencer 720 to sequence the bits according to snake type IIIconnection, another alternative implementation is to have the image bitssequencer 720 to have a fixed function to sequence the bits according tosnake type I and then execute appropriate microcodes to converting thebits in snake type I arrangement to a new arrangement suitable for snaketype III connection. Another possible implementation is to have themicrocodes to do the re-arrangement of the bits loaded from buffer 330to any desired sequence according to the actual connection type of theLED display panel.

The examples above are based on pixels in a single color, i.e., one biteach pixel. In most LED display applications, pixels are colored, somepartial and some full color. As discussed herein, when pixels arecolored, each pixel has different color components and therefore hasmore than one bit. For example, a picture may be dual colored with redand green color components. A picture may also be full colored so thateach pixel has all three color components, i.e., red, green, and blue.Each color component may have its own intensity, represented bydifferent gray scales represented by bits. Depending on resolution, thenumber of bits used to represent each color component may vary. It canbe a single bit in each color, representing two gray scales, e.g., onand off. There may also be more bits, e.g., 8 bits in each colorcomponent representing 256 intensity levels. In general, each colorcomponent is represented as a different image frame so that a full colorimage has three image frames, as shown in FIG. 1E. As discussed herein,according to the present teaching, when there are multiple bitsrepresenting each color component, the image data is re-organized sothat corresponding color bits in different color components are storedtogether, as shown in FIGS. 4A and 4B. This is to facilitate thecompression scheme, as shown in FIG. 4C, of the present teaching.

When there are more than a single color, the connection pattern may bemore complex and how the image bits are to be sequenced also differaccordingly. FIG. 12A shows a row of pixels in dual color where eachcolor light being individually driven by a separate column signal, inaccordance with an embodiment of the present teaching. As illustrated,each pixel has two color lights, red and green. For example, the firstpixel on the left has a red bit A31 and a green bit A30, the secondpixel has a red bit A29 and a green bit A28, etc. In this illustration,all red lights are driven by a column signal 1230 and all green lightsare driven by a different column signal 1240. FIG. 12B shows a differentrepresentation of the same connection pattern with separate columndrivers 1250 and 1260 driving two respective color components of pixels,in accordance with an embodiment of the present teaching. As seen,column driver 1250 has various links for delivering column signal 1230to red lights of a row of pixels, starting from the left most linksending signals to A31, A29, A27, A25, . . . . Column driver 1260 hasvarious links for delivering column signal 1240 to green lights of a rowof pixels, starting from the left most link sending signals to A30, A28,A26, A24, . . . . When lights for different colors are driven byseparate column signals, the bits in the bit based image blocks may notneed to be re-sequenced. However, usually, different colors of thepixels may be driven by the same column signal. In this case, a columnsignal used to drive different color components of the pixels needs totraverse different color lights and different pixels in a certainconnection pattern.

FIG. 13A shows how a column signal is used to drive both colorcomponents of pixels via a snake type I connection, in accordance withan embodiment of the present teaching. In this illustration, the samepixel row in dual color is provided with two corresponding colorcomponents, one being a row of red color of the pixels and the otherbeing green color of the pixels. Different from FIG. 12A, a singlecolumn signal 1310 in FIG. 13A is used to drive both red and greenlights of the pixels. Specifically, the column signal 1310 traverses allthe red and green lights of pixel in 1220 in a snake type I connectionpattern, i.e., first to A31 (red), then to A30 (green), A29 (red), A28(green), A27 (red), A26 (green), . . . , A17 (red), and to A16 (green).FIG. 13B shows a representation of using a column driver 1320 to drivecolumn signal 1310 through both color lights of all pixels in 1220 via asnake type I connection, in accordance with an embodiment of the presentteaching. As seen, the various links from the column driver 1320starting from the left most link send the column signal 1310 to all inthe order of A31, A30, A29, A28, . . . , traversing both red and greenlights of all pixels in the row.

To facilitate driving pixels of dual color via snake type I connectionpattern, bits in a bit based image block need to be re-sequenced. Asdiscussed herein, for an image with dual color, a bit based image blockretrieved from an alternate buffer has corresponding bits from bothcolor stored together. For example, if each color is represented using 8bits, then there will be 8 frames for the image. The first frame maystore the least significant bits of red and green for each pixel. Thesecond frame may store the second least significant bits of red andgreen for each pixel, . . . and the last frame may store the mostsignificant bits of red and green for each pixel. FIG. 13C shows contentin registers loaded from an alternate buffer 330 with pixels in dualcolor, in accordance with an embodiment of the present teaching. Asdiscussed herein, A31 and A30 are red and green bits from red and greencolor components, respectively, for the first pixel. A29 and A28 are abit from red and a corresponding bit from green, respectively, for thesecond pixel, etc.

To facilitate snake type I connection pattern, the bits as shown in FIG.13C need to be re-sequenced. FIG. 13D shows the result of sequencing thebits in registers as shown in FIG. 13C with pixels in dual color tofacilitate snake type I connection, in accordance with an embodiment ofthe present teaching. The re-sequenced bits are in the top row are nowordered as A31, A29, A27, A25, . . . , and the re-sequenced bits in thesecond row are now A30, A28, A26, A24, . . . so that when a columnsignal traverses in a snake type I connection pattern, it will achievethe traverse order of A31, A30, A29, A28, . . . , consistent with whatis shown in FIG. 13A. If the connection pattern for pixels in dual coloris snake type II, then a column signal used to drive both colorcomponent of all pixels in FIG. 13A will traverse in the order of A30,A31, A28, A29, . . . , (not shown). To accommodate the snake type IIconnection pattern for pixels in dual color, the color bits in FIG. 13Cwill be rearranged to produce bits in a first register in the order ofA30, A28, A26, . . . and in the second row in a new order of A31, A29,A27, . . . so that when a column signal traverse in a snake type IIconnection, it will deliver the signal in the order of A30, A31, A28,A29, . . . (not shown). If the connection pattern is snake type III,then the order of re-arranged bits will be A31, A30, A28, A29, A27, A26,A24, A25, . . . (now shown).

As discussed herein, when the image bits loaded from the buffer 330 needto be re-arranged to accommodate the connection type of the LED display,there may be different ways to achieve the re-arrangement appropriatefor the connection type. One is via sequencing performed by the imagebits sequencer 720, as shown in FIG. 9D and FIG. 13D. Another way is tocombine the use of the image bits sequencer 720 and the microcodes. Theimage bits sequencer 720 may be provided to sequence the image bitsaccording to snake type I connection. If the actual connection type issnake type II or III, microcodes may be executed to rearrange the bitsin snake type I arrangement to convert to bit orders for otherconnection types. For example, to convert from snake type I bitarrangement to snake type II arrangement, a simple operation of flippingthe order of each pair of bits will achieve the conversion.

FIG. 14A shows a single row of pixels in full color with each of thethree color components being driven by a separate column signal in astraight connection pattern, in accordance with an embodiment of thepresent teaching. As discussed herein, when the traverse cover a singlecolor with a straight through connection in each color component, itrequires no sequencing of the bits in a bit based image block. FIG. 14Bshows snake type I connection across different rows of pixels in eachcolor, in accordance with an embodiment of the present teaching. Asillustrated, there are three column signals, each is used to drive adifferent color but across two rows of pixels according to snake type Itraverse pattern. As marked therein, a pixel in a first row is 1410 anda corresponding pixel from a second row is 1420. Each of these pixels isstored with 3 color bits, red, green, and blue and they are arrangedtogether. For example, a red bit A31, a green bit A30, and a blue bitA29 of the first pixel of the first row; a red bit A28, a green bit A27,and a blue bit A26 of the first pixel of the second row (stored with thefirst pixel of the first row). Additionally, the second pixel of thefirst row has bits A25 (red), A24 (green), and A23 (blue); the secondpixel of the second row has bits A22 (red), A21 (green), and A20 (blue).A column signal 1430-1 for driving red bits of pixels in a snake type Iconnection (across rows) is driven to the red lights by a column driver1430-2. The column signal 1440-1 for driving green bits of pixels acrossrows in a snake type I connection is driven to the green lights by acolumn driver 1440-2. The column signal 1450-1 for driving blue bits ofpixels across rows in a snake type I connection is driven to blue lightsby a column driver 1450-2.

FIG. 14C shows content in registers with pixels from two rows are storedtogether in full color, in accordance with an embodiment of the presentteaching. As seen, the first three bits A31, A30, and A29 correspond tored, green, and blue bits of the first pixel from the first row 1410,the next three bits A28, A27, and A26 correspond to red, green, and bluebits of the first pixel from the second row and together it correspondsto 1420. FIG. 14D shows the result of sequencing these color bits ofpixels to facilitate driving each color component separately acrossdifferent rows in snake type I connection pattern, in accordance with anembodiment of the present teaching. As can be seen, through sequencingoperation, the red, green, and blue bits of different pixels are nowarranged in such a way that bits in each color are driven acrossdifferent rows in a way consistent with snake type I connection pattern.For example, in the red color, the column signal 1430-1 goes through A31(red of the first pixel from the first row), A28 (red of the first pixelfrom the second row), A25 (red of the second pixel of the first row),A22 (red of the second pixel from the second row), A19 (red of the thirdpixel from the first row), A16 (red of the third pixel from the secondrow), . . . etc. Similarly, in the green color, the column signal 1440-1goes through A30 (green of the first pixel from the first row), A27(green of the first pixel from the second row), A24 (green of the secondpixel of the first row), A21 (green of the second pixel from the secondrow), A18 (green of the third pixel from the first row), A15 (green ofthe third pixel from the second row), . . . etc. With regard to bluecolor, the column signal 1450-1 is driven through A29 (blue of the firstpixel from the first row), A26 (blue of the first pixel from the secondrow), A23 (blue of the second pixel of the first row), A20 (blue of thesecond pixel from the second row), A17 (blue of the third pixel from thefirst row), A14 (blue of the third pixel from the second row), . . .etc.

FIG. 15A shows a representation of separately driving each colorcomponents of pixels in full color separately in snake type IIconnection, in accordance with an embodiment of the present teaching. Asillustrated, the data is organized the same way as what is shown in FIG.14B, except that the connection type is snake type II, in which, insteadof starting with the pixel in the first row, it starts from the pixel ofthe second row and then zig zag between the first and second rows. FIG.15B shows the result of sequencing the bits in registers as shown inFIG. 14C with pixels in full color to facilitate driving color bits in asnake type II connections, in accordance with an embodiment of thepresent teaching. As discussed herein, this may be achieved viadifferent means. As shown previously, one is via sequencing performed bythe image bits sequencer 720. Another way is to combine the use of theimage bits sequencer 720 and the microcodes. The image bits sequencer720 may be provided to sequence the image bits according to snake type Iconnection. If the actual connection type is snake type II or III,microcodes may be executed to rearrange the bits in snake type Iarrangement to convert to bit orders for other connection types. Asshown above, to convert from snake type I bit arrangement to snake typeII arrangement, a simple operation of flipping the order of each pair ofbits will achieve the conversion.

The above various examples show how to sequence bits in bit based imagedata in order to accommodate different connection types used to linkdifferent pixels in an LED display screen. As shown in FIG. 7 ,sequencing operation is performed by the image bits sequencer 720. Asdiscussed herein, depending on the connection of each LED displayscreen, the information related to the connection type may be configuredin the connection profile 740 and is made available to the image bitssequencer 720. As discussed herein, based on the information about theconnection type, the image bits sequencer 720 may then activate theappropriate microcodes stored in 730 to perform the bit sequencing.Thus, the refresh processor 340 is capable of adapting to different LEDdisplay screens that connect LED unit panels in different ways. There-sequenced image bits are then sent to the special buffer 750, whichthen sends such image content, on a first in first out order, to the LEDrefresh unit 760. Based on such appropriately sequenced image bits, theLED refresh unit 760 transforms the image content into different controlsignals to be used to control how the lights associated with pixels inthe LED panels 770 are refreshed in order to deliver the visual effectof the image content.

FIG. 16 is a flowchart of an exemplary process of the refresh processor340, in accordance with an embodiment of the present teaching. Similarto the data transfer unit 320, the refresh processor 340 may alsooperate in two different phases. In the first phase, the refreshprocessor 340 is to be configured handle an LED display screen with acertain connection type. This is for deploying microcodes appropriatefor the specific connection type in hand. The second phase is an onlinephase to display image content on the LED display screen based on thebit based image data stored in alternate buffers 330-1 and 330-2.

In FIG. 16 , steps 1600 and 1610 are for the phase one, in whichinformation stored in 740 on connection type is accessed at 1600 andappropriate microcodes for the specified connection type are loaded at1610. The rest of the steps form a loop to traverse the entire image fordisplaying image content on an LED screen. As discussed herein, duringthe online phase of displaying image content on an LED display screen,the refresh processor 340 syncs its operation with the data transferunit 320 based on the commonly shared clock signal CLK. In this process,upon receiving a next clock signal at 1620, the image bits sequencer 720accesses, at 1630, the buffer pointer in order to retrieve, at 1640, thenext bit based image block from one of the alternate buffers pointed toby the buffer pointer. The image bits sequencer 720 then executes, at1650, the loaded microcodes suitable for the current connection type tosequence the image bits in the loaded bit based image block. There-sequenced image bits are then stored, at 1660, to the special buffer750, from where they can be accessed by the LED refresh unit 760, at1670, to generate, at 1680, various refreshing control signals accordingto the image content. Such generated control signals are then used bythe LED refresh unit 760 to refresh, at 1690, the lights on the LEDpanels.

As disclosed herein, the LED display framework according to the presentteaching organizes bits in an image in a way to maximize the processingspeed, minimizes required memory resources, and capable of adapting toLED display screens that adopt different connection types. Thesecharacteristics of the present teaching effectively address and remedythe deficiencies of the traditional solutions in LED display.

FIG. 17 is an illustrative diagram of an exemplary computing devicearchitecture that may be used to realize a specialized systemimplementing the present teaching in accordance with variousembodiments. Such a specialized system incorporating the presentteaching has a functional block diagram illustration of a hardwareplatform, which includes user interface elements. The computer may be ageneral purpose computer or a special purpose computer. Both can be usedto implement a specialized system for the present teaching. Thiscomputer 1700 may be used to implement any component of variouscomponents, as described herein. For example, the data transfer unit 320and/or the refresh processor 340 may be implemented on a computer suchas computer 1700, via its hardware, software program, firmware, or acombination thereof. Although only one such computer is shown, forconvenience, the computer functions relating to the LED display systemas described herein may be implemented in a distributed fashion on anumber of similar platforms, to distribute the processing load.

Computer 1700, for example, includes COM ports 1750 connected to andfrom a network connected thereto to facilitate data communications.Computer 1700 also includes a central processing unit (CPU) 1720, in theform of one or more processors, for executing program instructions. Theexemplary computer platform includes an internal communication bus 1710,program storage and data storage of different forms (e.g., disk 1770,read only memory (ROM) 1730, or random access memory (RAM) 1740), forvarious data files to be processed and/or communicated by computer 1700,as well as possibly program instructions to be executed by CPU 1720.Computer 1700 also includes an I/O component 1760, supportinginput/output flows between the computer and other components thereinsuch as user interface elements 1780. Computer 1700 may also receiveprogramming and data via network communications.

Hence, aspects of the methods of dialogue management and/or otherprocesses, as outlined above, may be embodied in programming. Programaspects of the technology may be thought of as “products” or “articlesof manufacture” typically in the form of executable code and/orassociated data that is carried on or embodied in a type of machinereadable medium. Tangible non-transitory “storage” type media includeany or all of the memory or other storage for the computers, processorsor the like, or associated modules thereof, such as varioussemiconductor memories, tape drives, disk drives and the like, which mayprovide storage at any time for the software programming.

All or portions of the software may at times be communicated through anetwork such as the Internet or various other telecommunicationnetworks. Such communications, for example, may enable loading of thesoftware from one computer or processor into another, for example, inconnection with conversation management. Thus, another type of mediathat may bear the software elements includes optical, electrical, andelectromagnetic waves, such as used across physical interfaces betweenlocal devices, through wired and optical landline networks and overvarious air-links. The physical elements that carry such waves, such aswired or wireless links, optical links, or the like, also may beconsidered as media bearing the software. As used herein, unlessrestricted to tangible “storage” media, terms such as computer ormachine “readable medium” refer to any medium that participates inproviding instructions to a processor for execution.

Hence, a machine-readable medium may take many forms, including but notlimited to, a tangible storage medium, a carrier wave medium or physicaltransmission medium. Non-volatile storage media include, for example,optical or magnetic disks, such as any of the storage devices in anycomputer(s) or the like, which may be used to implement the system orany of its components as shown in the drawings. Volatile storage mediainclude dynamic memory, such as a main memory of such a computerplatform. Tangible transmission media include coaxial cables; copperwire and fiber optics, including the wires that form a bus within acomputer system. Carrier-wave transmission media may take the form ofelectric or electromagnetic signals, or acoustic or light waves such asthose generated during radio frequency (RF) and infrared (IR) datacommunications. Common forms of computer-readable media thereforeinclude for example: a floppy disk, a flexible disk, hard disk, magnetictape, any other magnetic medium, a CD-ROM, DVD or DVD-ROM, any otheroptical medium, punch cards paper tape, any other physical storagemedium with patterns of holes, a RAM, a PROM and EPROM, a FLASH-EPROM,any other memory chip or cartridge, a carrier wave transporting data orinstructions, cables or links transporting such a carrier wave, or anyother medium from which a computer may read programming code and/ordata. Many of these forms of computer readable media may be involved incarrying one or more sequences of one or more instructions to a physicalprocessor for execution.

Those skilled in the art will recognize that the present teachings areamenable to a variety of modifications and/or enhancements. For example,although the implementation of various components described above may beembodied in a hardware device, it may also be implemented as a softwareonly solution—e.g., an installation on an existing server. In addition,the fraudulent network detection techniques as disclosed herein may beimplemented as a firmware, firmware/software combination,firmware/hardware combination, or a hardware/firmware/softwarecombination.

While the foregoing has described what are considered to constitute thepresent teachings and/or other examples, it is understood that variousmodifications may be made thereto and that the subject matter disclosedherein may be implemented in various forms and examples, and that theteachings may be applied in numerous applications, only some of whichhave been described herein. It is intended by the following claims toclaim any and all applications, modifications and variations that fallwithin the true scope of the present teachings.

We claim:
 1. A method implemented on at least one machine including atleast one processor, memory, and communication platform capable ofconnecting to a network for LED display, the method comprising: inresponse to a signal, transferring, via a bus connected between a memoryand a pair of two alternate buffers, a new bit-based image block storedin the memory to a first buffer of the pair of two alternate buffers;and transferring, via a bus connected between the pair of two alternatebuffers and an image bits sequencer, a bit-based image block previouslystored in a second buffer of the pair of two alternate buffers to theimage bits sequencer, wherein each time the signal is received, apointer is toggled to point from one buffer to the other buffer withinthe pair of two alternate buffers, the pointer identifying which bufferwithin the pair of two alternate buffers is to receive the new bit-basedimage block, such that the pair of two alternate buffers alternatereceiving the new bit-based image block and transferring a storedbit-based image block to the image bits sequencer; sequencing, at theimage bits sequencer by executing microcodes for a connection type ofdriving connections in unit panels within the LED display, the storedbit-based image block, resulting in a sequenced image block, andrefreshing lights of the LED display using the sequenced image block. 2.The method of claim 1, wherein the transferring of the new bit-basedimage block stored in the memory to the first buffer and thetransferring of the stored bit-based image block stored in the secondbuffer to the image bits sequencer occur synchronously.
 3. The method ofclaim 1, wherein the transferring of the new bit-based image blockstored in the memory to the first buffer is initiated by a data transferunit.
 4. The method of claim 3, wherein the sequencing of the storedbit-based image block and the refreshing of the lights of the LEDdisplay are initiated by a refresh processor.
 5. The method of claim 4,wherein the data transfer unit and the refresh processor aresynchronously operating on the pair of two alternate buffers.
 6. Themethod of claim 1, wherein a subsequent signal, after the signal, istransmitted upon the new bit-based image block being transferred intothe first buffer.
 7. The method of claim 1, further comprising:retrieving from storage the microcodes suitable to be executed.
 8. Themethod of claim 1, wherein the connection type of the panels is furtherbased on a pattern in which column drivers of panels within the LEDdisplay are connected, wherein the connection type comprises one of: asnake type I connection, a snake type II connection, and a snake typeIII connection.
 9. A machine readable and non-transitory medium havinginformation stored thereon for LED display, wherein the information,once read by a machine, causes the machine to perform: in response to asignal, transferring, via a bus connected between a memory and a pair oftwo alternate buffers, a new bit-based image block stored in the memoryto a first buffer of the pair of two alternate buffers; andtransferring, via a bus connected between the pair of two alternatebuffers and an image bits sequencer, a bit-based image block previouslystored in a second buffer of the pair of two alternate buffers to theimage bits sequencer, wherein each time the signal is received, apointer is toggled to point from one buffer to the other buffer withinthe pair of two alternate buffers, the pointer identifying which bufferwithin the pair of two alternate buffers is to receive the new bit-basedimage block, such that the pair of two alternate buffers alternatereceiving the new bit-based image block and transferring a storedbit-based image block to the image bits sequencer; sequencing, at theimage bits sequencer by executing microcodes for a connection type ofdriving connections in unit panels within the LED display, the storedbit-based image block, resulting in a sequenced image block, andrefreshing lights of the LED display using the sequenced image block.10. The machine readable and non-transitory medium of claim 9, whereinthe transferring of the new bit-based image block stored in the memoryto the first buffer and the transferring of the stored bit-based imageblock stored in the second buffer to the image bits sequencer occursynchronously.
 11. The machine readable and non-transitory medium ofclaim 9, wherein the transferring of the new bit-based image blockstored in the memory to the first buffer is initiated by a data transferunit.
 12. The machine readable and non-transitory medium of claim 11,wherein the sequencing of the stored bit-based image block and therefreshing of the lights of the LED display are initiated by a refreshprocessor.
 13. The machine readable and non-transitory medium of claim12, wherein the data transfer unit and the refresh processor aresynchronously operating on the pair of two alternate buffers.
 14. Themachine readable and non-transitory medium of claim 9, wherein asubsequent signal, after the signal, is transmitted upon the newbit-based image block being transferred into the first buffer.
 15. Themachine readable and non-transitory medium of claim 9, having additionalinformation stored which, when read by the machine, causes the machineto perform: retrieving from storage the microcodes suitable to beexecuted.
 16. The machine readable and non-transitory medium of claim 9,wherein the connection type of the panels is further based on a patternin which column drivers of panels within the LED display are connected,wherein the connection type comprises one of: a snake type I connection,a snake type II connection, and a snake type III connection.
 17. Asystem, comprising: a LED display; a pair of two alternate buffersconfigured for alternately storing and retrieving bit-based imageblocks; a memory; a bus connected between the memory and the pair of twoalternate buffers; an image bits sequencer; a machine readable andnon-transitory medium having information stored thereon, wherein theinformation, once read by the machine, causes the machine to perform: inresponse to a signal, transferring, via the bus connected between thememory and the pair of two alternate buffers, a new bit-based imageblock stored in the memory to a first buffer of the pair of twoalternate buffers; and transferring, via a bus connected between thepair of two alternate buffers and the image bits sequencer, a bit-basedimage block previously stored in a second buffer of the pair of twoalternate buffers to the image bits sequencer, wherein each time thesignal is received, a pointer is toggled to point from one buffer to theother buffer within the pair of two alternate buffers, the pointeridentifying which buffer within the pair of two alternate buffers is toreceive the new bit-based image block, such that the pair of twoalternate buffers alternate receiving the new bit-based image block andtransferring a stored bit-based image block to the image bits sequencer;sequencing, at the image bits sequencer by executing microcodes for aconnection type of driving connections in unit panels within the LEDdisplay, the stored bit-based image block, resulting in a sequencedimage block, and refreshing lights of the LED display using thesequenced image block.
 18. The system of claim 17, wherein thetransferring of the new bit-based image block stored in the memory tothe first buffer and the transferring of the stored bit-based imageblock stored in the second buffer to the image bits sequencer occursynchronously.
 19. The system of claim 17, wherein the transferring ofthe new bit-based image block stored in the memory to the first bufferis initiated by a data transfer unit.
 20. The system of claim 19,wherein the sequencing of the stored bit-based image block and therefreshing of the lights of the LED display are initiated by a refreshprocessor.